A lithium-ion flow battery is a flow battery that uses a form of lightweight lithium as its charge carrier.[1] The flow battery stores energy separately from its system for discharging. The amount of energy it can store is determined by tank size; its power density is determined by the size of the reaction chamber.
Dissolving a material changes its chemical behavior significantly. Flow batteries suspend grains of solid material in a liquid, which preserves its characteristics, making lithium's high energy density available to flow systems.
Lithium polysulfide
One device uses dissolved sulfur as the cathode, lithium metal as the anode and an organic solvent as the electrolyte.[2] Officially "membraneless", it uses a coating to separate anode from cathode. It uses a single tank and pump and reacts the LiS with lithium to produce power. The device operated for more than 2000 cycles without substantial degradation.[1][3]
When discharging, the lithium polysulfide absorbs lithium ions; releasing them when charging.[1] The demonstration device yielded energy density of 97 Wh/kg and 108 Wh/L with a 5M Li
2S
8 catholyte.[2]
LiFePO4
Reversible delithiation/lithiation of LiFePO
4 was successfully demonstrated using ferrocene derivatives. This device keeps the energy storage materials stored in separate tanks. The liquids remain stationary during operation. The device incorporated a lithium-ion permeable membrane.[4]
Lithium iodine
A cathode-flow lithium-iodine (Li–I) battery uses the triiodide/iodide (I
3−/I−) redox couple in aqueous solution. It has energy density of 0.33 kWh/kg because of the solubility of LiI in aqueous solution (≈8.2M) and its power density of 130 mW/cm2 at a current rate of 60 mA/cm2, 328 K. In operation, the battery attains 90% of the theoretical storage capacity, coulombic efficiency of 100%±1% in 2–20 cycles, and cyclic performance of >99% capacity retention for 20 cycles, up to total capacity of 100 mAh.[5]
LiTi2(PO4)3–LiFePO4
A semi-solid cell based on the LiTi
2(PO
4)
3–LiFePO
4 couple utilizes fluid electrodes that are electronically conductive. Simultaneous advection and electrochemical transport separates flow-induced losses from those due to underlying side reactions. Plug flow is used to achieve energy efficiency with non-Newtonian flow electrodes.
References
- 1 2 3 "Researchers Design a New Low Cost Lithium-Polysulfide Flow Battery". SciTech Daily. 2013-05-24. Retrieved 2013-12-27.
- 1 2 "New lithium polysulfide flow battery for large-scale energy storage". Green Car Congress. 2013-04-25. doi:10.1039/C3EE00072A. Retrieved 2013-12-27.
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(help) - ↑ Yang, Y.; Zheng, G.; Cui, Y. (2013). "A membrane-free lithium/polysulfide semi-liquid battery for large-scale energy storage". Energy & Environmental Science. 6 (5): 1552. doi:10.1039/C3EE00072A.
- ↑ Huang, Q.; Li, H.; Grätzel, M.; Wang, Q. (2013). "Reversible chemical delithiation/lithiation of LiFePO4: Towards a redox flow lithium-ion battery". Physical Chemistry Chemical Physics. 15 (6): 1793–1797. Bibcode:2013PCCP...15.1793H. doi:10.1039/C2CP44466F. PMID 23262995.
- ↑ Zhao, Y.; Byon, H. R. (2013). "High-Performance Lithium-Iodine Flow Battery". Advanced Energy Materials. 3 (12): 1630. doi:10.1002/aenm.201300627. S2CID 98455413.
External links
- Wang, Y.; He, P.; Zhou, H. (2012). "Li-Redox Flow Batteries Based on Hybrid Electrolytes: At the Cross Road between Li-ion and Redox Flow Batteries". Advanced Energy Materials. 2 (7): 770. doi:10.1002/aenm.201200100. S2CID 96707630.
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